Conductive film layer for hall effect device

ABSTRACT

A Hall effect device comprising: (a) an electrically-conductive layer or plate having a top surface; and (b) a ferromagnetic layer, where the conductive film or layer is composed of high mobility semiconductors. Also, a Hall effect device can have a ferromagnetic element that is a multilayer (e.g., a bilayer), and a device in which the Hall plate comprises an indium compound, germanium or mixtures thereof. The devices are useful for a variety of applications such as a memory element in a nonvolatile random access memory array (NRAM) and as a logic gate.

BACKGROUND OF THE INVENTION

1. Field of the Invention

The present invention relates generally to a Hall effect device. In particular, the present invention relates to a hybrid Hall effect device (i.e., a magneto-electronic device) comprising a semiconductor structure and a ferromagnetic element or layer. The devices according to the present invention are useful for various applications including, but not limited to, nonvolatile random access memory array (NRAM), use as a logic gate, field effect transistor (FET), and any other sensing element in the category of Hall effect devices.

2. Description of the Background Art

The semiconductor field effect transistor (FET), typically fabricated as a metal oxide semiconductor (MOSFET) structure on a silicon substrate or gallium arsenide device (GaAsFET) on a gallium arsenide substrate, is the building block of modern digital electronics. For example, memory cells for the storage of binary information and logic gates for the processing of digital data streams both use FET's as the primary components.

A standard representation for a classic four-terminal Hall plate is a cross centered in a square. Two opposing terminals on two opposing sides of the square are used for current bias I+ and I− (or voltage bias), and two other opposing terminals on the remaining two opposing sides are used as sensing probes for sensing a bipolar Hall voltage (or current).

Recently, certain modified Hall effect devices (i.e., a hybrid combination of a conventional Hall plate coupled to a ferromagnetic layer) have been disclosed. A modified Hall plate incorporates a ferromagnetic film that is usually fabricated to be electrically isolated from the Hall plate (e.g., by an insulating layer) but to cover a portion of the area of the Hall plate such that an edge of the ferromagnetic film is over a central region of the plate. Local, fringe magnetic fields from the edge of the ferromagnetic film are perpendicular to the plane of the plate, may point “up”′ or “down” depending on the orientation of the magnetization of the ferromagnetic film, and have an average value B_(av) in the active region of the device. For constant bias current the sensed Hall voltage (or current) has opposite polarity when the fringe fields are “up”′ compared with when they are “down.” The magnetization of the ferromagnetic film is typically in the plane of the ferromagnetic film and lies along an axis parallel with that of the bias current, but it is also possible to use a magnetic material with magnetization perpendicular to the plane. In the former case, the magnetization can have two stable states along the axis parallel with the bias current and each state corresponds to “up” or “down” fringe fields near the edge of the ferromagnetic film, positive or negative Hall voltage (or current), and a binary bit of information “1” or “0”. The magnetization state can be set (written) to be positive or negative by using the magnetic field associated with a positive or negative current pulse transmitted down an integrated write wire that is contiguous with the ferromagnetic film, as in U.S. Pat. No. 5,652,445 ('445) to Johnson, which is incorporated herein by reference for all purposes. It follows that such a device can be used as the nonvolatile storage element in an array of elements comprising a nonvolatile random access memory (NRAM).

The '445 patent involves an application in high density nonvolatile memory and logic gate environments. The '445 patent involves a conductive film layer, a ferromagnetic layer, a fringe magnetic field, and an electrical signal. Reference is also made to the '445 patent for further discussion of the Hall effect and other Hall effect devices.

The need exists to provide new, modified Hall effect devices with further enhancements. In particular, there is a significant need in the art for improved hybrid Hall effect devices that are more reliable for use in high density memory and logic environments than existing hybrid Hall effect devices.

SUMMARY OF THE INVENTION

Accordingly, it is an object of the present invention to provide a significantly improved hybrid Hall effect device that exhibits increased reliability in high density memory and logic environments.

It is also an object of the present invention to present novel materials systems to be used in the fabrication of hybrid Hall effect devices, with the effect of enhancing the operating speed and increasing the output signal level of the device.

It is another object of the present invention to provide a substantially improved hybrid Hall effect device in which the remanence of the magnetic component layer is larger and therefore the bistable output voltage (or current) is larger.

It is yet another object of the present invention to achieve a further improvement over existing hybrid Hall effect devices by providing devices with a square hysteresis loop of the ferromagnetic component, thereby improving the efficiency of the write process.

It is a further object of the present invention to achieve an improvement over existing hybrid Hall effect devices by providing devices with a lower coercivity of the ferromagnetic component, thereby lowering the power of the write process.

It is another object of the present invention to achieve a further improvement over existing hybrid Hall effect devices by providing devices in which the perpendicular component of magnetic field is increased in the active region of the device, thereby increasing the output voltage (or current).

It is also an object of the present invention to achieve a further improvement over existing hybrid Hall effect devices by providing devices with decreased switching time of the ferromagnetic component layer.

It is also an object of the present invention to achieve a further improvement over existing hybrid Hall effect devices by providing devices with novel materials systems that have high mobility and produce larger output voltages (or currents).

It is yet another object of the present invention to achieve a further improvement over existing hybrid Hall Effect devices by providing devices incorporating novel materials systems that are compatible with the fabrication requirements of the support circuitry, such as select, sense and amplification circuits.

These and other objects of the invention are accomplished by providing a Hall effect device comprising:

(a) an electrically-conductive layer or plate having a top surface and capable of carrying an electrical current;

(b) a ferromagnetic layer comprising a material selected from the group consisting of: (i) ferrites and (ii) perovskite ferromagnetic oxides; and

(c) where an electrical signal can be generated in response to the fringe magnetic field acting on the electrical current.

In another embodiment, the objects of the present invention are achieved by providing a Hall effect device comprising:

(a) an electrically conductive layer or plate having a top surface; and

(b) a ferromagnetic multilayer comprising at least a first magnetic layer and a second magnetic layer.

In yet another embodiment of the present invention, the objects of the present invention are achieved by a Hall effect device comprising:

(a) an electrically-conductive layer or plate having a top surface; and.

(b) a ferromagnetic layer,

(c) where the electrically conductive layer or plate comprises an indium compound or a germanium compound.

Thus, in one aspect, it has been discovered that certain classes of ferromagnetic materials (e.g., ferrites or perovskite ferromagnetic oxides) can be used for the fabrication of modified Hall effect devices to achieve faster switching times.

In addition, it has been discovered that the ferromagnetic layer can be fabricated as one component of a multilayer (e.g., bilayer), where the second component is a thin magnetic (ferromagnetic or antiferromagnetic) layer for magnetically biasing the first layer. The result of the magnetic bias can be a larger remanence and/or a hysteresis loop that is not symmetric with respect to zero applied field. Other optional layers in the multilayer include, but are not limited to, buffer layer(s) for improving the quality of growth of the ferromagnetic layer and/or bias layer or a passivation layer for protecting the multilayer from environmental degradation.

Furthermore, it has been discovered that a shape anisotropy can be employed to reduce the coercivity (and therefore reduce the amplitude of current in the write pulse) of the ferromagnetic component, and that an additional element can be used to close flux lines and alter the perpendicular field component in a desirable way. For example, to provide a higher concentration of flux, to prevent stray flux from affecting other parts of the device, and to provide a more perpendicular orientation of the lines of the flux.

Additionally, in considering the class of semiconducting materials used to fabricate the Hall plate, it has been discovered that several different semiconducting materials, with mobilities larger than those of silicon or gallium arsenide, can be used to achieve larger readout voltages (or currents).

BRIEF DESCRIPTION OF THE DRAWINGS

A more complete appreciation of the invention will be readily obtained by reference to the following Description of the Preferred Embodiments and the accompanying drawings in which like numerals in different figures represent the same structures or elements, wherein:

FIG. 1 is a schematic representation of a hybrid Hall effect device, a modified Hall plate, according to an embodiment of the present invention.

FIG. 2 is a perspective view of a hybrid Hall effect device, a modified Hall plate, according to an embodiment of the present invention.

FIG. 3 is a cross sectional view of a portion of a hybrid Hall effect device, a modified Hall plate, according to an embodiment of the present invention, showing an element with high magnetic permeability that can be used to facilitate magnetic flux return and increase the perpendicular component of magnetic field in the active region of the device.

FIG. 4 is a top view of a hybrid Hall effect device, a modified Hall plate, according to an embodiment of the present invention, showing a ferromagnetic component with a preferred shape anisotropy and two lateral elements of high magnetic permeability used to facilitate magnetic flux return.

FIG. 5 is a cross sectional view of a portion of a hybrid Hall effect device, a modified Hall plate, according to an embodiment of the present invention, showing a portion of a lateral element of high magnetic permeability used to facilitate magnetic flux return.

DESCRIPTION OF THE PREFERRED EMBODIMENTS

The basic structure of the modified Hall effect devices of the present invention is described in the previously mentioned U.S. Pat. No. 5,652,445, which is incorporated herein by reference.

As discussed above, it has been discovered that novel materials systems enhance device performance. As shown in FIG. 2, a ferromagnetic layer (e.g., a film) 22 may, if desired, be electrically isolated from a Hall plate (or layer) 12 by an insulating layer 32 and cover a portion of the plate so that an edge 26 of the ferromagnetic layer is over a region approximately in line with sense probes 18 and 20. The insulating layer 32 may cover the portion of the Hall plate 12 that is directly beneath the ferromagnetic layer 22, or may cover all of the Hall plate 12 and may serve the additional function of passivating portions of the device structure and offering protection against degradation during and after processing.

It is possible to fabricate the hybrid Hall effect device so that a ferromagnetic gated FET is provided, where the Hall plate 12 is the conducting channel of an FET and the ferromagnetic layer 22 is fabricated on top of, or as a portion of, the FET gate electrode.

Transition metal ferromagnets, such as PERMALLOY (Ni_(0.8)Fe_(0.2)), iron, and cobalt can be used as the ferromagnetic material in hybrid Hall effect devices. In a first embodiment of the present invention, certain classes of ferromagnetic materials (e.g., ferromagnetic insulators) offer enhanced performance of several device characteristics. An example of one category of these materials is the ferrites, which are magnetic oxides containing ferric oxide (Fe₂O₃) as their basic magnetic component. If desired, these ferrites may contain dopants such as Mn, Co, Ni, Zn and mixtures thereof. Another example is a category of materials known as the perovskite ferromagnetic oxides, such as strontium ruthenate. Other suitable classes of materials include, but are not limited to ferromagnetic semiconductors and rare-earth transition metal alloys. The ferromagnetic material should be magnetically ordered at the desired operating temperature, have sufficiently high magnetic moment to be useful and have an appropriate coercivity. Metallic magnetic materials have large moments and reasonable coercivities, with switching times typically of order nsec. Some semiconducting magnetic materials have faster switching times, 0.1 nsec or less, but the have smaller values of magnetization. Some insulating magnetic materials have fast switching times, approximately 1 psec, but relatively small magnetizations. Both semiconductors and insulators have poor conductivity and can thereby be used without the addition of an insulating layer. This is an advantage because the magnitude of the fringe field is largest at positions very close to the magnetic layer. When no additional insulating layer is used, the magnetic layer can be positioned very close to the Hall plate. The result is that devices fabricated with insulating or semiconducting materials may have output values that are as large as those that use metallic magnetic layers, but they may be able to take advantage of the faster switching speed.

Ferrites typically have a spinel structure, or a variation of the spinel structure, such that local moments with number n_(A) in one atomic plane (A) are oriented in one direction and the local moments with number n_(B) in the next plane (B) are oriented in the opposite direction. Since the number of moments per plane are not equal, i.e., n_(A)≠n_(B), the material has a net magnetization M. The magnitude of the saturation magnetization M_(s) of the ferrites as measured by a standard laboratory magnetometer, is typically on the order of about 4 πM_(s)=3,000 Oe, which is much less than that of transition metal ferromagnets, e.g. about 4 πM_(s)=11,000 Oe for PERMALLOY and about 4 πM_(s)=20,000 Oe for iron. Some ferrites have relatively large magnetizations, such as manganese zinc ferrite (MnZnFe₂O₄), with approximately 4 πM_(s)=4,000 Oe. Other properties of ferrites are similar to those of metallic ferromagnets: like the transition metal ferromagnets, the ferrites have a strong shape anisotropy that confines the magnetization to the plane of a film, they have low values of coercivity (from approximately 1 Oe to about 100 Oe), and they can be fabricated with one or more easy magnetization axes in, the film plane.

The local magnetic fields at the edge 26 of the ferromagnetic film or layer 22 (refer to FIG. 2) provide the mechanism that enables the Hybrid Hall device to operate. The magnitude of these fields is proportional to the saturation magnetization M_(s) of the ferromagnetic film or layer 22, and the output of the device is thus proportional to the value of M_(s). Although the ferrites have lower M_(s) than metallic magnetic materials, the local magnetic fields may have sufficiently large magnitudes when the distance from the edge 26 to the Hall plate 12 is minimized. The magnitude of the field is diminished as the vertical distance from the edge 26 to the layer 12 is increased.

Hybrid Hall effect devices that incorporate transition metal ferromagnets usually function best when the ferromagnetic layer is electrically isolated from the Hall plate 12 by a thin insulating layer (layer 32 in FIG. 2) of thickness Z₀. Z₀ can vary greatly, from orders less than or about 1 nm to as great as or greater than orders of tens of nm. When the metallic ferromagnetic layer 22 is not isolated in this way, a large portion of the bias current is shunted through the metallic ferromagnetic layer and the voltage detected at terminals 18 and 20 is reduced. However, the insulating layer has the effect of placing the carriers in the Hall plate 12 at a greater distance from the edge 26. The local magnetic fields have diminished value at this greater distance, and the output of the device is therefore reduced from the optimum value.

Because magnetic insulators such as the ferrites or perovskites are electrically insulating, a ferromagnetic layer 22 comprised of such a material or of a magnetic semiconductor can be fabricated directly on top of the Hall plate 12. The carriers in the Hall plate 12 are now in closer proximity to the edge 26 and the local magnetic fields are relatively large, so that device output is increased. The carriers in the Hall plate 12 are now in closer proximity to the edge 26 and the local magnetic fields are relatively large, so that device output is increased. It follows that a hybrid Hall effect device fabricated with an insulating ferromagnetic material directly on top of the conductive Hall plate may have output levels that are comparable with a device fabricated using a metallic ferromagnetic element and a thin insulating layer.

Magnetic insulators have other properties that offer additional benefits. They are chemically stable, and it is typically not necessary to passivate a ferrite ferromagnetic layer against environmental degradation. Furthermore, the time T _(f) required to reverse the magnetization of the ferromagnetic layer 22 sets a limitation on the speed of some device operations, such as the write operation. The value of T _(f) is about 1 to about 10 psec for magnetic insulators such as the ferrites, which is about two to three orders of magnitude shorter than the value for transition metal ferromagnets, which have T _(f) of about 1 nsec. Thus, Hybrid Hall devices fabricated using magnetic insulators for the ferromagnetic layer 22 may operate with frequencies as high as about 10¹² Hz (1 THz).

In another aspect of the above-described embodiment, a ferromagnetic layer comprised of a magnetic insulator can be fabricated as a portion of the insulating layer between the gate electrode and channel, or can be fabricated on top of said insulating layer.

The above remarks about magnetic insulators apply to all embodiments of the present invention (and also to any modified Hall effect Device, such as MAGFET, magnetotransistor, etc.).

When the ferromagnetic layer is a magnetic insulator based on ferrite(s) or perovskite ferromagnetic oxides, the Hall plate can be made from various materials including, but not limited to Si, Ge, GaAs, SiGe, Bi, or compound semiconductor heterostructures.

The thicknesses and the sizes of the various layers making up the devices described in the embodiments described above are not particularly limited. Typically, however, the ferromagnetic layer has a thickness of order 10 to 100 nm, and that of the Hall plate is the order of 1 to 10 nm.

In yet another embodiment of the present invention, it has been discovered that one important technique for enhancing the properties of the ferromagnetic layer is to fabricate the ferromagnetic layer as a portion of a magnetic multilayer (e.g., a bilayer) in which one or more of the other component layers have magnetic properties that influence the properties, of the ferromagnetic layer. One example of this technique is to fabricate the ferromagnetic layer 22 as a magnetic bilayer F_(b) with two components, F₁ and F₂ in order to stiffen the anisotropy and enhance the remanence. The component F₁ is a magnetic material such as a transition metal ferromagnet or a ferrite, and has a thickness of about 10 nm to 1.0 μm, and has a relatively large saturation magnetization M_(s) (e.g., about 800 Oe/4π to about 1600 Oe/4π) so that the fringe magnetic fields generated at edge 26 are relatively large. Typically, the material that comprises F₁ is chosen to have a small coercivity H_(c) from about 1.0 Oe to 100 Oe, as measured on a standard laboratory magnetometer. The component F₂ is usually a magnetic material with a thickness of about 1 to about 10 nm, has a small value of saturation magnetization of about <10,000 Oe, can be fabricated beneath F₁ or on top of F₁, and has magnetic properties that interact with those of F₁.

For example, F₂ can be an antiferromagnetic insulator such as nickel oxide (NiO) or manganese iron (Mn_(1−x)Fe_(x), wherein x is approximately 0.5). A bilayer comprised of PERMALLOY for F₁ with a thickness of approximately 100 nm and nickel oxide for F₂ with a thickness of approximately 2 nm will have the same value of saturation magnetization as a single layer of PERMALLOY. The coercivity will be increased, H_(c) of about 40 Oe, but the remanence M_(r) of the bilayer will also be substantially increased to a value comparable with the saturation magnetization, M_(s). A single, comparable layer of PERMALLOY would have a smaller coercivity, H_(c) of about 10 Oe, but would also have a smaller remanence, M_(r) approximately equal to M_(s)/5. The remanant magnetization is a key device parameter because the output voltage is typically detected in the nonpowered state, H=0, which is equivalently the remanent state. Thus, fabricating the ferromagnetic layer 22 as a bilayer can enhance device performance by enhancing the remanent magnetization.

Furthermore, the component F₂ can be used to alter the magnetic properties of F_(b) in other ways. For example, a magnetic bias can be induced so that the hysteresis loop of F_(b) is offset from zero by a chosen value. This is useful to introduce asymmetries in device characteristics. For example, a write pulse of a given amplitude for one polarity may be required to set one state of the device, whereas a write pulse of a different amplitude for the opposite polarity would be required to reset the device to the original state. More generally, ferromagnetic layer 22 can be a multilayer comprised of n layers including the ferromagnetic material F₁, one or more bias layers F₂, and one or more nonmagnetic layers N_(i). The nonmagnetic layers are provided as buffer layers in order to enhance the growth, and therefore the characteristics, of the other layers. For example, a thin layer (30 nm thick) of zinc selenide is, in some circumstances, a suitable buffer layer for enhancing the properties of thin iron films, resulting in films with smaller coercivities and larger remanence. As another example, Ag or Cu may be used as a nonmagnetic buffer layer to provide a smooth, nonreactive interface for the subsequent growth of Fe films, resulting in smaller coercivities and higher remanence. The nonmagnetic layers may also act as passivation layers, protecting one or more of the layers in the multilayer from degradation during or after processing. For example, a thin layer, approximately 5 nm thick, of Cu passivated Fe films and reduces their coercivity.

The above comments about fabricating the ferromagnetic layer as a magnetic bilayer or multilayer apply to all embodiments of the present invention, including the modified Hall effect device and the ferromagnetic gated FET, and apply to layers where the component F₁ is any ferromagnetic material.

Novel Materials for the Hall Plate

The Hall plate 12 (refer to FIG. 1 and FIG. 2) can be fabricated from any material whose carriers are characterized by a large Hall coefficient such as doped silicon or doped gallium arsenide (semiconductors), or bismuth (a metal). It has been discovered that Hall plates fabricated from several novel material systems afford enhanced device performance.

Thus, in a further embodiment of the present invention, (e.g., 10 in FIG. 1 or FIG. 2), each cell is typically biased by a supply (or bias) voltage V_(B) from terminal 14 to terminal 16. The voltage response of a Hall plate with aspect ratio act of approximately unity (ratio of length to width) and with optimally placed sensor probes 18 and 20 (placed approximately in the center of the plate 12) is as follows:

V _(H)=(0.7)μV _(B) B _(⊥)

where μ is the mobility in units of (m²/V−s) and V_(H) is in volts. For the hybrid Hall effect device, B_(av) is substituted for B_(⊥) (in tesla). A lithographic asymmetry in the placement of the probes 18 and 20 can be introduced to change the output from symmetrically bipolar, V_(out)=±V_(H), to unipolar, e.g. V_(out)=0, 2V_(H). This kind of biased output is well suited to accommodate a sense amplifier that discriminates between zero and a positive readout voltage V_(r). For such a device, the output voltage magnitude is twice the Hall voltage and the voltage to be sensed is:

V _(r)=(1.4)μV _(B) B _(av)

The mobility of the Hall material is the only factor that relates the readout voltage directly to the bias voltage. For purposes of this disclosure, the sensed value V_(r) is discussed in the context of the readout voltage of a memory cell, but the sensed value may also, represent the contents of a cell that is being used in a logic operation or information processing environment. Furthermore, it is understood to those skilled in the art that the readout signal V_(r) may eventually be sensed either as a voltage or a current.

The energy dissipation E_(j) during a read process, E_(j)=V_(B) ²/R, where R is the resistance of the element (the resistance from terminal 14 to 16), is determined by R and therefore by the amount of doping n of the Hall plate material and its thickness d. A second consideration also determines the value of the thickness d: the magnitude B_(av) decays with increasing distance r from the ferromagnetic layer, having the functional form B_(av)∝1/r, Apart from other considerations, the thickness should be minimized in order to minimize the decay of B_(av). Values of d of about 100 nm or less are typical.

In general, power losses are minimized for low values of bias voltage and V_(B) values of about 1 V are considered desirable. Sense amplifiers for commercial DRAM typically are capable of reliable discrimination between V=0 and V=V_(r)=20 mV, and the desired readout level of DRAM is designed to be V_(r)≧100 mV to allow for signal degradation and cross-talk. These values are adopted as guides for calculations made herein. However, there are a variety of sense amplifier circuits and it is clear to those skilled in the art that a modification in the parameters of a sense amplifier will alter the values of the parameters of a Hybrid Hall Effect element. In particular, the present invention is expected to provide superior signal to noise ratio (SNR) and minimal cross-talk, and it is plausible that the sense amplifier may require readout voltage values as low as 10 mV.

The indium compounds and germanium listed below have been found to possess good characteristics. These materials enhance device performance of the improved Hall plate when used as the material system to fabricate the Hall plate 12. It is particularly important to use materials with optimum properties as device dimensions shrink, and it is likely that hybrid Hall effect devices will be fabricated on a submicron scale.

Indium Antimonide (InSb)

Indium Antimonide (InSb) has the largest mobility of commercial semiconductor materials, μ=8 m²/V−s, and presently has industrial use in applications where conventional Hall plates are used to sense an external magnetic field. When used in the fabrication of a modified Hall plate (with typical width of sense probes 18 and 20 of 1 micron, and a ferromagnetic film whose edge generates an average field of magnitude B_(av)=500 Oe=0.05 tesla), a bias source of 1 Volt gives a sense voltage V_(r)=0.56 V, a value much larger than the sense amplifier requires. Accordingly, InSb is an excellent material choice, and a bias voltage as low as 180 mV will provide an adequate sense voltage V_(r)=100 mV. The doping profile and layer thickness of the InSb film can be chosen for a given environment, and it is well known that the mobility of thin films (thickness approximately 100 nm) is diminished from the bulk value and is highly sensitive to the conditions of growth. For example, use of an appropriate buffer layer can result in a value of mobility that is close to the bulk value. Even without intentional doping, a 100 nm thick film has a resistance of about 300 ω) per square, an appropriate value. Films with thicknesses in the range of about 20 to about 200 nm will have excellent properties. Indium antimonide has such a large Hall effect that it can be used in applications where a current output at terminals 18 and 20 is desired.

Indium Arsenide (InAs)

Indium Arsenide (InAs) has a large mobility, μ=3.3 m²/V−s. When used in the fabrication of a modified Hall plate (with typical characteristics as given above), a bias source of 1 Volt gives a sense voltage V_(r)=0.23 V, a value much larger than the sense amplifier requires. A bias voltage as low as 440 mV will provide an adequate sense voltage V_(r)=100 mV. The mobility of thin indium arsenide films is sensitive to the growth conditions and can vary by an order of magnitude. For example, a film of InAs with thickness about 15 nm grown on a gallium arsenide substrate with a thick intervening buffer layer of aluminum antimonide (AlSb) has a mobility approximately equal to the bulk value when capped by a thin layer (about 15 nm) of AlSb. This structure may have a final passivation coating of InAs or GaSb with thickness about 2 nm. Such a buried InAs layer has a resistance per square of about 150 ω, an appropriate value. In general, InAs films have high mobilities when grown on an appropriate buffer layer and when capped with an appropriate insulating layer. Such films, with thicknesses in the range of about 10 to about 100 nm, will have excellent properties and will be well suited for use in the modified Hall plate of the present invention.

Thus, InAs is another excellent material choice, and the Hall effect is sufficiently large that it can be used in applications where current output is desired. Furthermore, the circuitry associated with supporting the improved Hall devices, such as address selection and sense amplification, can be fabricated using GaAs FET technology.

Germanium (Ge)

Germanium (Ge) is inexpensive, can be fabricated as a thin film on silicon, typically using a thin buffer layer of SiGe alloy at the interface, and has a higher mobility than silicon, μ=0.39 m²/V−s. It is widely available and can be readily microfabricated. When used in the fabrication of a modified Hall plate (with typical characteristics as given above), a bias source of 1 Volt gives a sense voltage V_(r)=27 mV, a value adequate for many environments. A bias voltage of 3.7 V results in a sense voltage V_(r)=100 mV. The doping profile and layer thickness can be chosen for a given environment. A further advantage of using Ge films is that silicon technology can be Used for fabrication of the support circuitry.

A related materials system is a modulation doped Si/Ge heterostructure. These layers typically have mobility of μ=0.2 m²/V−s, somewhat higher than Si.

Indium Phosphide (InP)

Doped InP layers grown on insulating Indium phosphide wafers have a mobility of about μ=1.0 m²/V−s. When used in the fabrication of a modified Hall plate (with typical characteristics as given above), a bias source of 1 Volt gives a sense voltage V_(r)=0.08 V, an adequate value for the sense amplifier. A further advantage to the use of InP based heterostructures is that the support circuitry can be made using InP FET technology, a well developed technology for high speed circuits.

Design Parameters for the Ferromagnetic Element

Flux Closure:

The local, magnetic fringe field at the edge of the ferromagnetic element generates the voltage (or current) signal that enables operation of the hybrid Hall effect device, and is also the source of the demagnetizing field. As the size of the element shrinks, the demagnetizing field magnitude increases and the coercivity of the element becomes larger. It has been discovered that the stray field lines can be directed down towards the layer of carriers by using a high permeability magnetic element that facilitates closure of the magnetic flux. In this way, the demagnetizing field is reduced, the coercivity is minimized, magnetic interference between neighboring cells is also minimized, and the magnetic flux that acts on the carriers is increased.

In FIG. 3, a material with high magnetic permeability is deposited as a layer 48 under (or in) the buffer layer 46. An example of a suitable material is PERMALLOY, such as Ni_(0.8)Fe_(0.2). Other examples include, but are not limited to, mu-metal; alloys of Ni, Co, and Fe; alloys of FeCo; and soft magnetic oxides. A magnetic field line 52 originating at the edge 26 of ferromagnetic layer 22 is drawn downwards to the high permeability material 48, and the field line closes to the opposite end of the ferromagnetic layer (not pictured). The magnitude of the perpendicular component of field at the plane of the carrier channel 44 is increased, thereby increasing B_(av).

Ideally, for an application involving an array of devices the flux closure material 48 would be individually patterned and aligned beneath each ferromagnetic layer. The magnetic state of the ferromagnetic layer would be set by fringe fields from write pulses applied to an integrated write wire, and coupling to the closure element 48 would be so weak that the write process would not be affected. In some environments, it may be possible to fabricate the flux closure layer 48 as a continuous layer. The material will break into domains, with a domain associated with each ferromagnetic layer in the array, and walls at the edges of these domains may generate fringe fields that could degrade performance.

In some materials systems it may not be possible to find an appropriate material that can be grown under (or as a part of) the buffer layer 46. However, it is still possible to provide a magnetic element for flux closure. FIG. 4 depicts a Hall plate 12 with ferromagnetic element 22. One or more ferromagnetic components 62 (and/or 64) can be fabricated in close proximity, to the side of ferromagnetic layer 22. In the cross sectional view of FIG. 5, the Hall cross has been patterned using a mesa etch that etches through the insulating layers 32 and 44, the channel layer 12, and the buffer layer 46, to the surface of the substrate 50. In practice, the mesa step might etch only a small distance past the interface between the channel 12 and the buffer layer 46. The flux closure element 62 (and/or 64) is then microfabricated such that it is substantially beneath the level of the channel 12. In this case, an appropriate material for the flux closure element 62 (and/or 64) is PERMALLOY, e.g. Ni_(0.8)Fe_(0.2). Field lines (such as line 52) from the edge 26 of ferromagnetic layer 22 are drawn down towards the closure element 62 (and/or 64). The magnitude of the perpendicular component of field at the plane of the carrier channel 44 is increased, thereby increasing B. Using this kind of fabrication, it would be beneficial to planarize the device prior to fabrication of the write wires. Also, the use of a flux closure element permits fabrication of a vertical cell, where trenches are etched in the semiconductor substrate and the magnetic elements are fabricated with their long axes perpendicular to the substrate plane.

Shape Anisotropy

A variety of magnetic anisotropies can be used to influence the magnetic characteristics of the ferromagnetic layer. An important design criteria involves shape anisotropy. It has been discovered that a long rectangle, with an aspect ratio of about 5 to 1, promotes formation of an easy magnetization axis along the long axis of the rectangle resulting in low coercivity and high remanence. It has been discovered that an ellipse, with a similar aspect ratio of about 4 to 1, results in slightly lower coercivities than a rectangle.

FIG. 4 depicts a top view of a Hall plate 12 with ferromagnetic element 22. Prototype cells appropriate for Very Large Scale Integration (VLSI) have been fabricated with PERMALLOY and cobalt films with dimensions approximately 1 μm by 5 μm. Prototype cells appropriate for Ultra Large Scale Integration (ULSI) have been fabricated with PERMALLOY films with dimensions approximately 0.5 μm by 2.5 μm. The ferromagnetic film 22 in FIG. 4 has been drawn with a shape approximating an ellipse. As device dimensions shrink, square edges are rounded and fabrication favors the ellipse. A ULSI prototype with a PERMALLOY film has achieved a coercivity of 25 Oe with a very high remanence. 

What is claimed is:
 1. A Hall effect device comprising: a conductive film layer having a top surface and capable of carrying an electrical current; a ferromagnetic layer having a configurable magnetization orientation, and covering a first portion of the top surface, and not a second portion, such that a fringe magnetic field substantially normal to such surface can be generated by an edge portion of the ferromagnetic layer; wherein an electrical signal can be generated in response to the fringe magnetic field acting on the electrical current in said conductive film layer; and wherein said conductive film layer is comprised of at least one indium compound selected from the group consisting of indium antimonide, indium arsenide, and indium phosphide.
 2. The device of claim 1, further including a first sensor coupled to a first edge of said conductive film layer.
 3. The device of claim 1, further including a first sensor coupled to a first edge of said conductive film layer, and a second sensor coupled to a second edge of the conductive film layer, opposite to the first edge, such that the electrical signal is a voltage generated substantially along an axis joining the first and second sensors.
 4. The device of claim 1, wherein said device is a field effect transistor (FET) in which said electrically-conductive layer is a conducting channel.
 5. The device of claim 1, further including a buffer layer; wherein said buffer layer is in contact with said ferromagnetic layer.
 6. The device of claim 1, wherein said ferromagnetic layer has a top surface in an anisotropic shape.
 7. The device of claim 6, wherein said anisotropic shape is an ellipse or a rectangle with an aspect ratio of at least about 3; wherein said aspect ratio is defined as the ratio of the length to the width.
 8. A Hall effect device comprising: a conductive film layer having a top surface and capable of carrying an electrical current; a ferromagnetic layer having a configurable magnetization orientation, and covering a first portion of the top surface, and not a second portion, such that a fringe magnetic field substantially normal to such surface can be generated by an edge portion of the ferromagnetic layer; wherein an electrical signal can be generated in response to the fringe magnetic field acting on the electrical current in said conductive film layer; and wherein said conductive film layer is comprised of at least one selected from the group consisting of germanium and silicon germanium.
 9. The device of claim 8, further including a first sensor coupled to a first edge of said conductive film layer.
 10. The device of claim 8, further including a first sensor coupled to a first edge of said conductive film layer, and a second sensor coupled to a second edge of the conductive film layer, opposite to the first edge, such that the electrical signal is a voltage generated substantially along an axis joining the first and second sensors.
 11. The device of claim 8, wherein said device is a field effect transistor (FET) in which said electrically-conductive layer is a conducting channel.
 12. The device of claim 8, further including a buffer layer; wherein said buffer layer is in contact with said ferromagnetic layer.
 13. The device of claim 8, wherein said ferromagnetic layer has a top surface in an anisotropic shape.
 14. The device of claim 13, wherein said anisotropic shape is an ellipse or a rectangle with an aspect ratio of at least about 3; wherein said aspect ratio is defined as the ratio of the length to the width. 